Smart tool for enterprise-wide version control of codes during software integration and deployment

ABSTRACT

Embodiments of the present invention provide a system for controlling versions of codes during software integration and deployment. The system is typically configured for creating a program increment development branch in a first environment system, opening a first iteration candidate under the program increment development branch with a first iteration version number associated with a program increment version range of the program increment development branch, receiving at least one first development code from a first user via a smart tool user interface, moving the first development code to the first iteration candidate, receiving a first input from the first user to lock the first iteration candidate, locking the first iteration candidate, and closing the first iteration candidate.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation application of co-pending patentapplication Ser. No. 15/887,576, filed Feb. 2, 2018 and titled “SMARTTOOL FOR ENTERPRISE-WIDE VERSION CONTROL OF CODES DURING SOFTWAREINTEGRATION AND DEPLOYMENT,” the entire disclosure of which is herebyincorporated herein by reference.

FIELD

The present invention relates to enterprise-wide version control ofcodes during software integration and deployment.

BACKGROUND

Continuous delivery and continuous integration of application softwarecan be a difficult and time consuming process. Coordinating with aplurality of users and using multiple applications for integrating anddeploying the application software decreases the efficiency and consumesmore amount of time. Thus, there exists a need for a system whichintegrates and deploys the application software efficiently.

SUMMARY

The following presents a simplified summary of one or more embodimentsof the present invention, in order to provide a basic understanding ofsuch embodiments. This summary is not an extensive overview of allcontemplated embodiments, and is intended to neither identify key orcritical elements of all embodiments nor delineate the scope of any orall embodiments. Its sole purpose is to present some concepts of one ormore embodiments of the present invention in a simplified form as aprelude to the more detailed description that is presented later.

Embodiments of the present invention address the above needs and/orachieve other advantages by providing apparatuses (e.g., a system,computer program product and/or other devices) and methods forenterprise-wide version control of codes during software integration anddeployment. The system embodiments may comprise one or more memorydevices; a smart tool stored in the one or more memory devices, thesmart tool comprising one or more modules with instructions executableby one or more processing devices operatively coupled to the one or morememory devices, wherein the one or more processing devices areconfigured for executing the instructions to create a program incrementdevelopment branch in a first environment system, wherein the programincrement development branch comprises a program increment versionrange; open a first iteration candidate under the program incrementdevelopment branch with a first iteration version number, wherein thefirst version number is associated with the program increment versionrange; create a release development branch in the first environmentsystem, wherein the release development branch comprises a releaseversion range; open a first release candidate under the releasedevelopment branch with a first release version number, wherein thefirst release version number is associated with the release versionrange; receive at least one first development code from a first user viaa smart tool user interface; in response to receiving the firstdevelopment code, move the first development code to the first iterationcandidate; receive a first input from the first user to lock the firstiteration candidate; and lock the first iteration candidate based onreceiving the first input from the first user and close the firstiteration candidate.

In some embodiments, the one or more processing devices are configuredfor executing instructions in the one or more modules to deploy thefirst iteration candidate to a second environment system in response toclosing the first iteration candidate.

In some embodiments, the one or more processing devices are configuredfor executing instructions in the one or more modules to in response toclosing the first iteration candidate, open a second iteration candidateunder the program increment development branch with a second iterationversion number, wherein the second iteration version number isconsecutive to the first iteration version number; receive a seconddevelopment code associated with the first ruleset from at least one ofthe first user or a second user; in response to receiving the seconddevelopment code, move the second development code to the seconditeration candidate; receive a second input from at least one of thefirst user or the second user to lock the second iteration candidate;lock the second iteration candidate based on receiving the first inputfrom the first user and close the second iteration candidate; and inresponse to closing the second iteration candidate, open a thirditeration candidate under the program increment development branch witha third iteration version number, wherein the third iteration versionnumber is consecutive to the second iteration version number.

In some embodiments, the one or more processing devices are configuredfor executing instructions in the one or more modules to deploy thefirst iteration candidate and the second iteration candidate to a secondenvironment system in response to closing the second iterationcandidate.

In some embodiments, the one or more processing devices are configuredfor executing instructions in the one or more modules to: in response todeploying the first iteration candidate and the second iterationcandidate to the second environment system, perform a plurality of testson the first iteration candidate and the second iteration candidate;determine that the plurality of tests on the first iteration candidateand the second iteration candidate are successful; move the firstiteration candidate and the second iteration candidate to the firstrelease candidate with the first release version number.

In some embodiments, the one or more processing devices are configuredfor executing instructions in the one or more modules to: deploy thefirst release candidate to a third environment system on a predeterminedcycle end date associated with a first release cycle.

In some embodiments, the one or more wherein the one or more processingdevices are configured for executing instructions in the one or moremodules to open a second release candidate under the release developmentbranch with a second release version number in response to deploying thefirst release candidate to the third environment system, wherein thesecond release version number is associated with the release versionrange and is consecutive to the first release version number.

In some embodiments, receiving the first development code comprisesreceiving a first data instance and a first framework candidateassociated with the first development code from the first user via thesmart tool user interface.

In some embodiments, the first data instance and the first frameworkcandidate are moved to the first iteration candidate with the firstdevelopment code.

In some embodiments, the first development code and the seconddevelopment code are incremental changes.

In some embodiments, the first development code and second developmentare associated with a single feature.

In some embodiments, the first development code and the seconddevelopment code are associated with different features.

The features, functions, and advantages that have been discussed may beachieved independently in various embodiments of the present inventionor may be combined with yet other embodiments, further details of whichcan be seen with reference to the following description and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Having thus described embodiments of the invention in general terms,reference will now be made to the accompanying drawings, where:

FIG. 1 illustrates a block diagram illustrating a system environment forproviding a smart tool for continuous integration and continuousdeployment of application software, in accordance with embodiments ofthe present invention.

FIG. 2 illustrates a block diagram for smart tool application with oneor more modules, in accordance with embodiments of the presentinvention.

FIG. 3A is a flowchart illustrating a general process flow forautomatically integrating and deploying the application software, inaccordance with embodiments of the present invention.

FIG. 3B is a flowchart illustrating a continuation of the generalprocess flow for automatically integrating and deploying the applicationsoftware, in accordance with embodiments of the present invention.

FIG. 3C is a flowchart illustrating a continuation of the generalprocess flow for automatically integrating and deploying the applicationsoftware, in accordance with embodiments of the present invention.

FIG. 4 is a flowchart illustrating a general process flow for rulesetversioning and creation of iteration candidates and release candidates,in accordance with embodiments of the present invention.

FIG. 5 is a block diagram illustrating the process of deployment ofapplication software, in accordance with embodiments of the presentinvention.

FIG. 6 is a block diagram illustrating the ruleset versioning and movingthe development codes received from the user into iteration candidatesand release candidates based on the duration of the iteration cycles andthe release, in accordance with embodiments of the present invention.

FIG. 7 is a block diagram illustrating the orchestration of the softwareintegration and deployment process in one or more environment systems bythe smart tool, in accordance with embodiments of the present invention.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

Embodiments of the invention will now be described more fullyhereinafter with reference to the accompanying drawings, in which some,but not all, embodiments of the invention are shown. Indeed, theinvention may be embodied in many different forms and should not beconstrued as limited to the embodiments set forth herein; rather, theseembodiments are provided so that this disclosure will satisfy applicablelegal requirements. In the following description, for purposes ofexplanation, numerous specific details are set forth in order to providea thorough understanding of one or more embodiments. It may be evident;however, that such embodiment(s) may be practiced without these specificdetails. Like numbers refer to like elements throughout.

Today there are many steps application developers must complete todeploy certain software within an entity. There is a need for developingand deploying a framework for automating and simplifying the process. Anexample of such framework is the Pega® Platform, which is provided byPegasystems Inc. of Boston, Mass. It provides for an adaptive,cloud-architected software that empowers people to rapidly deploy, andeasily extend and change application to meet strategic business needs,providing capabilities in content and resource management and businessprocess management. This framework functions to automate the workflow oftasks, building and delivering application software.

Systems, methods, and computer program products are herein disclosedthat provide for integrating and deploying one or more development codesassociated with application software. Typically, conventional processfor integrating and deploying the one or more development codes isperformed by a number of teams comprising one or more users bytransferring the one or more development codes to and fro betweendifferent applications. For example, the present systems may use oneapplication for controlling versions of the one or more developmentcodes and may use a different application for packaging the one or moredevelopment codes. Typically a user transfers the code to and frobetween different applications. Such process is prone to human errorsand each of the different applications may not perform properly all thetime, thereby delaying the process of integration and deployment of theapplication software and decreasing the efficiency of the system.Therefore, there exists a need for a system which provides end to endintegration and deployment of the application software.

The present system provides a smart tool or smart Continuous Integrationand Continuous Deployment (CICD) application which is responsible forintegrating and deploying the one or more development codes. The presentsystem eliminates the need for transfer of the one or more developmentcodes between multiple users and multiple applications and provides aunified solution to perform integration and deployment of multiplesoftware applications in parallel. One or more modules of the smart CICDapplication comprise instructions for performing various steps indifferent phases of development of application software i.e., planning,development, build and deploy, testing, and release. Smart CICDapplication is built utilizing the features of a framework for deployingsoftware (e.g., Pega® platform) and provides an end to end solutionincluding gathering application prerequisites, controlling version ofone or more development codes received from one or more users, packagingand deploying the one or more development codes, testing of the packageddevelopment code, and deploying the packaged development codes toreal-time environment making the application software available for endusers. Moreover, the present system ensures timely delivery of theapplication software to the end user without any delays, therebyincreasing the efficiency of the system.

In accordance with embodiments of the invention, the terms “resourceentity system” may include any organization that is involved indevelopment of application software. In some embodiments, the resourceentity system may be any organization that implements operations orprocess management application development. In an exemplary embodiment,the resource entity system may be an organization that processesfinancial transactions including, but not limited to, banks, creditunions, savings and loan associations, card associations, settlementassociations, investment companies, stock brokerages, asset managementfirms, insurance companies and the like. Furthermore, embodiments of thepresent invention use the term “user” or “customer.” It will beappreciated by someone with ordinary skill in the art that the user orcustomer may be a customer of the financial institution or a potentialcustomer of the financial institution or an employee of the financialinstitution.

Many of the example embodiments and implementations described hereincontemplate interactions engaged in by a user with a computing deviceand/or one or more communication devices and/or secondary communicationdevices. Furthermore, as used herein, the term “user computing device”or “mobile device” may refer to mobile phones, personal computingdevices, tablet computers, wearable devices, smart devices and/or anyportable electronic device capable of receiving and/or storing datatherein.

A “user interface” is any device or software that allows a user to inputinformation, such as commands or data, into a device, or that allows thedevice to output information to the user. For example, the userinterface include a graphical user interface (GUI) or an interface toinput computer-executable instructions that direct a processing deviceto carry out specific functions. The user interface typically employscertain input and output devices to input data received from a usersecond user or output data to a user. These input and output devices mayinclude a display, mouse, keyboard, button, touchpad, touch screen,microphone, speaker, LED, light, joystick, switch, buzzer, bell, and/orother user input/output device for communicating with one or more users.

A “system environment”, as used herein, may refer to any informationtechnology platform of an enterprise (e.g., a national or multi-nationalcorporation) and may include a multitude of servers, machines,mainframes, personal computers, network devices, front and back endsystems, database system and/or the like.

FIG. 1 illustrates enterprise-wide software integration and deploymentsystem environment 100, in accordance with embodiments of the invention.As illustrated in FIG. 1, one or more resource entity systems 10 areoperatively coupled, via a network 2, to user computer systems 20, adevelopment environment system 30, a testing environment system 40, anacceptance test environment 50, production environment system 60, one ormore server systems (not shown), and/or one or more other systems (notillustrated). In this way, the user 4 (e.g., one or more associates,employees, agents, contractors, sub-contractors, third-partyrepresentatives, customers, or the like), through a user application 27(e.g., web browser, dedicated or smart Continuous Integration andContinuous Deployment (CICD) application, or the like), may accessresource entity applications 17 (e.g., website, smart ContinuousIntegration and Continuous Deployment (CICD) application, or the like)of the resource entity systems 10 to submit one or more developmentcodes associated with application development to the resource entitysystems 10. In some embodiments, the smart CICD application or tool maybe a part of an independent smart Continuous Integration and ContinuousDeployment (CICD) system. In such an embodiment, the smart ContinuousIntegration and Continuous Deployment (CICD) system is maintained andoperated by the resource entity systems 10. The smart ContinuousIntegration and Continuous Deployment (CICD) system may comprise one ormore processing devices operatively coupled to the one or more memorydevices and configured to execute computer readable code stored in theone or more memory devices.

In some embodiments, the development environment system 30, the testingenvironment system 40, the acceptance test environment system 50, andthe production environment system 60 may be a part of the resourceentity systems 10. The development environment system 30, the testingenvironment system 40, the acceptance test environment system 50, andthe production environment system 60 may comprise one or more processingdevices operatively coupled to the one or more memory devices andconfigured to execute computer readable code stored in the one or morememory devices. In some embodiments, the development environment system30, the testing environment system 40, the acceptance test environmentsystem 50, and the production environment system 60 may be a part ofsingle environment system, wherein the single environment system may bemaintained by the resource entity systems 10.

The network 2 may be a global area network (GAN), such as the Internet,a wide area network (WAN), a local area network (LAN), or any other typeof network or combination of networks. The network 2 may provide forwireline, wireless, or a combination of wireline and wirelesscommunication between systems, services, components, and/or devices onthe network 2.

As illustrated in FIG. 1, the resource entity systems 10 generallycomprise one or more communication components 12, one or more processingcomponents 14, and one or more memory components 16. The one or moreprocessing components 14 are operatively coupled to the one or morecommunication components 12 and the one or more memory components 16. Asused herein, the term “processing component” generally includescircuitry used for implementing the communication and/or logic functionsof a particular system. For example, a processing component 14 mayinclude a digital signal processor component, a microprocessorcomponent, and various analog-to-digital converters, digital-to-analogconverters, and other support circuits and/or combinations of theforegoing. Control and signal processing functions of the system areallocated between these processing components according to theirrespective capabilities. The one or more processing components 14 mayinclude functionality to operate one or more software programs based oncomputer-readable instructions 18 thereof, which may be stored in theone or more memory components 16.

The one or more processing components 14 use the one or morecommunication components 12 to communicate with the network 2 and othercomponents on the network 2, such as, but not limited to, the componentsof the user computer systems 20, the development environment system 30,the testing environment system 40, the acceptance test environmentsystem 50, and the production environment system 60, and/or othersystems. As such, the one or more communication components 12 generallycomprise a wireless transceiver, modem, server, electrical connection,electrical circuit, or other component for communicating with othercomponents on the network 2. The one or more communication components 12may further include an interface that accepts one or more networkinterface cards, ports for connection of network components, UniversalSerial Bus (USB) connectors and the like.

As further illustrated in FIG. 1, the resource entity systems 10comprise computer-readable instructions 18 stored in the memorycomponent 16, which in one embodiment includes the computer-readableinstructions 18 of the resource entity application 17 (e.g., websiteapplication, smart CICD application, or the like). In some embodiments,the one or more memory components 16 include one or more data stores 19for storing data related to the resource entity systems 10, including,but not limited to, data created, accessed, and/or used by the resourceentity application 17. The smart CICD application may include one ormore modules, wherein the one or more modules comprise instructionsexecutable by the one or more processing components 14. The developmentenvironment system 30, the testing environment system 40, the acceptancetest environment system 50, and the production environment system 60 mayinclude one or more memory components, wherein the one or more memorycomponents may include one or more development codes associated with theapplication development.

As illustrated in FIG. 1, plurality of users 4 may access the resourceentity application 17, or other applications, through a user computersystem 20. The user computer system 20 may be a desktop, mobile device(e.g., laptop, smartphone device, PDA, tablet, or other mobile device),or any other type of computer that generally comprises one or morecommunication components 22, one or more processing components 24, andone or more memory components 26. The plurality of users may be anyemployees of the resource entity system. For example, the plurality ofusers may be application program developers, business analysts, and/orthe like. In addition, the system environment 100 may also include usercomputer systems of one or more end users, wherein the one or more endusers access the application software deployed by the system on the usercomputer systems.

The one or more processing components 24 are operatively coupled to theone or more communication components 22 and the one or more memorycomponents 26. The one or more processing components 24 use the one ormore communication components 22 to communicate with the network 2 andother components on the network 2, such as, but not limited to, theother user computer systems, the development environment system 30, thetesting environment system 40, the acceptance test environment system50, and the production environment system 60, and/or other systems. Assuch, the one or more communication components 22 generally comprise awireless transceiver, modem, server, electrical connection, or othercomponent for communicating with other components on the network 2. Theone or more communication components 22 may further include an interfacethat accepts one or more network interface cards, ports for connectionof network components, Universal Serial Bus (USB) connectors and thelike. Moreover, the one or more communication components 22 may includea keypad, keyboard, touch-screen, touchpad, microphone, mouse, joystick,other pointer component, button, soft key, and/or other input/outputcomponent(s) for communicating with a user of the plurality of users 4.In one embodiment of the present invention, the smart CICD applicationin the user computer systems 20 may comprises a smart tool userinterface to display information associated with the applicationdevelopment.

As illustrated in FIG. 1, the user computer systems 20 may havecomputer-readable instructions 28 stored in the one or more memorycomponents 26, which in one embodiment includes the computer-readableinstructions 28 for user applications 27, such as smart CICD application(e.g., apps, applet, or the like), a web browser or other apps thatallow the user to take various actions, including allowing the user toaccess applications located on other systems, or the like. In someembodiments, the user utilizes the user applications 27, through theuser computer systems 20, to access the resource entity applications 17to submit one or more development codes associated with the applicationdevelopment. Moreover, in some embodiments the user may also utilize theuser applications 27 to check the status of the application development.

Referring now to FIG. 2, a block diagram 200 is provided for smart CICDapplication. The smart CICD application described herein may utilize oneor more features of the enterprise software such as Pega® to facilitatecontinuous integration and continuous development of the applicationsoftware. As shown in FIG. 2, the smart CICD application comprises oneor more modules, wherein the one or more modules may include a planningmodule 210, a development module 220, a build and deploy module 230, atesting module 240, a release module 250 and/or the like. Each of theone or more modules include one or more instructions that can beexecuted by one or more processors. In some embodiments, the planningmodule 210, the development module 220, the build and deploy module 230,the testing module 240, the release module 250 may be separate modules.In some other embodiments, the planning module 210, the developmentmodule 220, the build and deploy module 230, the testing module 240, therelease module 250 may be part of a unified single module. In someembodiments, any of the planning module 210, the development module 220,the build and deploy module 230, the testing module 240, or the releasemodule 250 may be combined into one single module. For example, thetesting module 240 and the release module 250 may be combined into onemodule. In some other embodiments, the planning module 210, thedevelopment module 220, the build and deploy module 230, the testingmodule 240, or the release module 250 may have overlapping instructionsdescribed in the process flows 300 and 400.

The planning module 210 of the smart CICD application includes one ormore instructions for release planning. The release planning may berelease or delivery of application software or incremental release orincremental delivery of the application software to one or more endusers. Release of the application software may be performed in differentcycles. In some embodiments, duration of each release cycle may betwelve months. In alternate embodiments, the duration of each releasecycle may be more or less than twelve months. Each release cycle mayinclude one or more iterations. For example, the release cycle of theapplication software may include twenty features that need to bedelivered to the one or more end users at the end of the release cycleand each iteration of the release cycle may include one feature of thetwelve features. In another example, each iteration may include morethan one feature. In some embodiments, duration of each iteration may beone week. In alternate embodiments, the duration of each iteration ismore or less than one week. Each iteration may have multiple iterationcandidates as illustrated in FIG. 5, wherein each of the iterationcandidates may include one or more development codes associated withrulesets, data instances, and framework candidates. The planning modulecomprises instructions for framework onboarding and applicationonboarding which include creation of development branches and settingversion ranges for release candidates and iteration candidates. In someembodiments, creation of version ranges is based on user input whichcomprises number of release cycles, number of iteration cycles, durationof each release cycle, duration of each iteration cycle, number oftechnical features, and/or the like. Upon receiving the user input, thesystem reserves version ranges for release candidates associated withrelease cycles and iteration candidates associated with iterationcycles. In some embodiments, the system automatically assigns versionranges based on a previous history of releases associated with theapplication software. In some embodiments, the planning module maycreate development branches for program increments and releasedevelopment as illustrated in FIG. 6.

Instructions for release planning may include gathering one or morerequirements from a plurality of users. The plurality of users may beemployees of the resource entity or third parties. For example, thesystem may gather the one or more requirements from business analystsand/or the like. In some embodiments, the planning module 210 maycomprise instructions for gathering technical requirements from theplurality of users associated with a first release. For example, thesystem via a smart tool user interface, may prompt the plurality ofusers to input one or more features or functions to be included in theapplication software for the first release. The technical requirementsor features or functions may be grouped to form one or more rule-sets.The rule-sets are used by the plurality of users to develop the code ofthe application software. For example, one or more applicationdevelopers may develop the program code or the source code based on therule-sets. In some embodiments, the planning module 210 may compriseinstructions to set up environment required for the development of theapplication software. For example, if the development of the applicationsoftware needs one or more platforms such as Java runtime environment,Python environment, and/or the like, the system may install the one ormore platforms in the one or more environment systems shown in FIG. 1and the user computer systems 20. In some embodiments, the planningmodule 210 may comprise instructions to identify applicationprerequisites. For example, the system may identify that connections arerequired to one or more external databases or servers for theapplication software development and may establish the connections. Inanother example, the system may identify that the application softwaredevelopment is dependent on some parts of development code of anotherapplication software and may download or copy the parts of thedevelopment code of another application software stored in the resourceentity system or other open source third party system (not shown) intothe one or more environment systems and the user computer system 20. Inyet another example, the system may identify that the applicationsoftware development is dependent on previous one or more developmentcodes and frameworks associated with a previous iteration cycle orrelease cycle and may verify the availability of the previous one ormore development codes, data instances, and framework candidatesassociated with the previous release cycle or iteration cycle. In suchan example, if any of the previous one or more development codes, datainstances, and framework candidates are missing from the user computersystem 20 or the one or more environment systems, the system maydownload or copy the missing previous one or more development codes tothe user computer system 20 and the one or more environment systems. Inanother example, the system may identify system configuration requiredfor the application software and may notify a user. For example, if thedevelopment of application software needs system requirements such as‘n’ gigabytes Random Access Memory and may notify the software developerinvolved in the development of the application software. In someembodiments, the planning module 210 may comprise instructions forcreating release instructions. For example, the system may automaticallyset the release date and calculate the number of iterations needed withor without user input. In one embodiment, the planning module 210 maycomprise instructions for notifying the plurality of users via the smarttool user interface about the status of the environment setup,identification of application prerequisites, and the creation of releaseinstructions. For example, the system may notify the plurality of usersthat the environment set up is complete and that the applicationprerequisites exist in the one or more environment systems. The systemmay also notify the plurality of users about the one or morerequirements, the release date, and the iteration end date.

The development module 220 may comprise instructions for controllingversions during the development phase of the application softwaredevelopment. Once the planning module 210 notifies the plurality ofusers, the plurality of users may develop the code. Each of theplurality of users may submit one or more development codes to thesystem and the system may save the one or more development codes in thedevelopment environment system 30 under different versions of iterationcandidates and release candidates. The one or more development codes maybe a part of a single unified development code associated with theapplication software. Each of the one or more development codes mayinclude at least one technical features or technical functions.Controlling versions of the iteration candidates and release candidatesis illustrated in FIG. 4 through FIG. 7. The development module 220 maycomprise instructions for locking and unlocking versions of iterationcandidates and release candidates. For example, the system may lock aversion of the iteration candidate which comprises at least onedevelopment code submitted by a first user to prevent other users frommaking changes to the development code, wherein the locked developmentcode is stable and without any errors. In one embodiment, the system maycomprise instructions for performing unit testing on the one or moredevelopment codes submitted by the plurality of users based oninstructions received from the plurality of users. Unit testing is anapplication software testing method using which the development code istested to cover all possible cases in which the development code mayfail. Additionally, the development module 220 may comprise instructionsfor controlling versions of framework candidates.

The build and deploy module 230 comprises instructions for packaging oneor more development codes associated with an iteration cycle or arelease cycle. For example, the one or more development codes associatedwith one or more technical features submitted by the plurality of usersfor a release cycle or iteration cycle are bundled or archived.Additionally, the build and deploy module may package frameworkcandidates and data instances along with the one or more developmentcodes. In some embodiments, the system may identify the most recentversion of each of the one or more development codes and may package themost recent version of the one or more development codes. For example,the user submits a development code to the system and after moving thedevelopment code into an iteration candidate, the user may make a smallchange to the already submitted code stored in the iteration candidateas a new version or sub version of the already submitted developmentcode. In some other embodiments, the system may identify all existingversions of each of the one or more development codes and may packageall existing versions of each of the one or more development codes. Insome other embodiments, the system may identify the most latest versionof the development code in other environment systems such as the testingenvironment system 40, acceptance test environment system 50, productionenvironment system 60 and may compare the most latest version in otherenvironment systems with a most recent version in the developmentenvironment system. The system may then package all the missing versionsof the one or more development codes. In one embodiment, the build anddeploy module may comprise instructions for deploying the packageddevelopment code to a second environment system, wherein the secondenvironment system may be the testing environment system 40 or theacceptance test environment system 50. The packaged development codecomprises one or more development codes, framework candidates, and datainstances. In some embodiments, the testing environment system 40 andthe user acceptance test environment system 50 may be a unified testingenvironment system. In one embodiment, the build and deploy module 230comprises instructions for performing an integration diagnostic check toverify that one or more connections with a plurality of systems areactive. For example, the smart CICD application may be communicatingwith the plurality of systems to perform one or more functions describedherein. The system performs a diagnostic check to verify that theconnections with the plurality of systems are active. In one example,the system performs the diagnostic check to verify database connections.In another example, the system may verify development code connections.In other words, the development code may be associated with anotherdevelopment code from a different application and the system may verifyconnections with the another development code. In some embodiments, thebuild and deploy module 230 comprises instructions for performingdatabase deployment. In prior art systems, the database deploymentprocess is a manual task, wherein a user performs the databasedeployment associated with the application which includes updatingdatabase tables such as creating or deleting database rows or columns.The present invention enables automatic database deployment associatedwith the application. In one embodiment, the build and deploy module 230comprises instructions for preparing release notes. Release notes is adocument comprising a list of all the technical features or technicalfunctions included in the packaged development code, wherein the releasenotes may be sent to the one or more end users on the release cycle dateor the iteration cycle date. In one embodiment, the build and deploy 230comprises instructions for restarting the application associated withthe development code of the application software. For example, an oldversion of the application may be running, the system after deployingthe packaged development code may restart the application to run theapplication with new technical features included in the packageddevelopment code. In one embodiment, the build and deploy 230 isconfigured to verify that the development code submitted by theplurality of users meets a set of standards. This step may be performedbefore packaging the one or more development codes or even before movingthe development codes received form the one or more users into iterationcandidates. For example, to maintain a unique coding standard throughouta resource entity, the resource entity system may place the set ofstandards. The system verifies that each of the one or more developmentcodes meets the set of standards.

The testing module 240 comprises instructions to facilitateimplementation of one or more tests on the packaged development code.Once the packaged development code is deployed to the testingenvironment system 40, the testing module 240 may be configured tofacilitate implementation of unit testing, regression testing, andperformance testing on the packaged development code. In someembodiments, the system may facilitate implementation of the one or moretests by a user. The user may be an application developer, anapplication test engineer, and/or the like. The user may manuallyimplement the one or more tests and the system facilitates the testingprocess such as making testing scripts associated with the one or moretests available for the user, providing access to the packageddevelopment code stored in the one or more environment systems, and/orthe like. In alternate embodiments, the system may automatically executescripts associated with the one or more tests to automatically performtesting on the packaged development code. In such an embodiment, thefinal testing process may be reviewed by a user. Automatic execution ofthe scripts may be associated with historical data related to thetesting of packaged development codes associated with other similarapplication software. The historical data may be stored in data store 19and/or data store 29. Regression testing is an application softwaretesting method to verify that the application software still functionsthe same way after integration of the new technical functions in thepackaged development code. Performance testing is an applicationsoftware testing method to test the performance of the applicationsoftware after integration of the new technical functions in thepackaged development code. The testing module 240 also comprisesinstructions to facilitate implementation of a user acceptance test. Theuser acceptance test is an application software testing method to createproduction like scenarios or real-time scenarios and test theapplication software using the real-time scenarios to verify thefunctionality and the performance of the application software after theintegration of the new technical functions in the packaged developmentcode. In some embodiments of the present invention, wherein the testingenvironment system 40 and the acceptance test environment system 50 areseparate systems, the system after deploying the packaged developmentcode to the test environment system 40 facilitates implementation of theone or more tests on the packaged development code. After the packageddevelopment code has passed the one or more tests, the system may deploythe packaged development code to the acceptance test environment system50 to perform the user acceptance test on the packaged development code.In alternate embodiments of the present invention, wherein the testingenvironment system 40 and the acceptance test environment system 50 area unified testing environment system, the build and deploy module 230 ofthe system deploys the packaged development code to the unified testingenvironment system. Upon deployment of the packaged development code tothe unified testing environment system, the testing module 240 of thesystem may facilitate implementation of the one or more tests includingthe user acceptance test on the packaged development code.

Once the packaged development code has passed the one or more tests, therelease module 250 comprises instructions to deploy the packageddevelopment code to the production environment system 60. The productionenvironment system 60 is the real time system where the applicationsoftware is delivered to the one or more end users. The release module250 comprises instructions for facilitating implementation of a smoketest on the packaged development code. Smoke test is an applicationsoftware testing method to verify that main functionalities of theapplication software are functioning without any errors afterintegration of the new technical functions. The release module 250comprises instructions for validation of the application software afterdeployment of the packaged development code to the productionenvironment system 60. The release module 250 comprises instructions toroll back the packaged development code deployed to the productionenvironment system when the smoke test or the validation isunsuccessful. For example, the system rolls back to the most stableversion of the application software based on determining that thevalidation of the application software is unsuccessful after deploymentof the packaged development code. The smart CICD application and the oneor more modules of the smart CICD application may simultaneously deployand integrate more than one packaged development codes associated withone or more software applications to multiple environment systems.

In some embodiments, the one or more modules of the smart CICDapplication implement some or all the instructions described in FIG. 3A,3B, and 3C by calling one or more functions or scripts stored in thedata store 19 of the resource entity system. For example, regressiontest scripts may be stored in the resource entity system and the testingmodule (while performing the one or more tests including the regressiontest) may call the regression test scripts stored in the resource entitysystem. In some embodiments, the one or more modules of the smart CICDapplication may perform some or all the instructions described in FIG.3A, 3B, and 3C after receiving an input and/or in automatic responsefrom a user. In one exemplary embodiment, the input may be an approvalfrom a user associated with the resource entity to perform one or moreinstructions. For example, the smart CICD, in some embodiments may onlydeploy packaged development code to the one or more environment systemsafter receiving an approval from a manager and/or the like; whereas inother embodiments, the smart CICD application may automatically deploypackaged development code to the one or more environment systems. Invarious embodiments, the smart CICD application 200 may not include eachof the other modules discussed herein. For example, the smart CICDapplication may not include the testing module 240. In such aconfiguration, when the process discussed herein reaches the appropriatestage, the smart CICD application 200 may send instructions to thetesting module 240. The instructions may cause the testing module 240 toperform one or more of the tests discussed elsewhere herein such as aunit test or a regression test. In some embodiments, the testing module240 may be stored and/or executed on a separate system than the smartCICD application 200, and in other embodiments, the testing module 240may be stored and/or executed on the same system as the smart CICDapplication 200, but may be considered a separate application or modulefrom the smart CICD application 200. In such a case, the testing module240 may require an application call or instructions to be sent to thetesting module 240 from the smart CICD application 200 for it tocommence testing.

Referring now to FIG. 3, a general process flow 300 is provided forintegration and deployment of application software. The smart CICDapplication of the system is capable of performing the steps in theprocess flow 300. As shown in block 302, the system identifies one ormore application prerequisites for the application development of anapplication. Application perquisites may be one or more developmentcodes, one or more databases, one or more other applications, systemconfigurations and/or the like. As shown in block 304, the systemgathers the one or more application prerequisites required for theapplication development. For example, the system may identify that theapplication software development is dependent on some parts ofdevelopment code of another application software and may download orcopy the parts of the development code of another application softwareinto the one or more environment systems and the user computer system20. In another example, the system may identify system configurationrequired for the application software and may notify a user.

As shown in block 306, the system initiates application onboardingprocess, wherein the application onboarding process comprisescalculating and reserving version range for release candidates anditeration candidates. The version ranges of release candidates anditeration candidates are independent and do not conflict with eachother. As explained previously, release or delivery of applicationsoftware is performed in different release cycles. Each release cyclecomprises multiple iterations or iteration cycles. Each release cyclecomprises one or more release candidates and each iteration cyclecomprises one or more iteration candidates. Iteration candidates of oneor more iteration cycles are combined to form a release candidate. Thesystem based on the duration of each iteration cycle and release cycle,calculates a number of release candidates required for each of themultiple release cycles and a number of iteration candidates requiredfor each of the multiple iteration cycles. As such, the systemdetermines the version ranges for release candidates and iterationcandidates. Release candidates and iteration candidates are explained indetail in FIG. 5 through FIG. 7. The system, as part of the applicationonboarding process, may create a development branch for one or morerulesets, wherein the development branch is used to store one or moredevelopment codes associated with one or more rulesets. In someembodiments, the development branch may be used to develop one or moredevelopment codes temporarily before pushing or tagging the one or moredevelopment codes into the iteration candidates and release candidates.The system may reserve version ranges for release candidates anditeration candidates under the development branch and open an iterationcandidate to receive one or more development codes from one or moreusers. For example, the system may open a development branch with aversion range of ‘01-01-01’ through ‘01-01-99’ and then open aniteration candidate ‘01-01-01’ to receive the one or more developmentcodes. In one embodiment, the system creates a program incrementdevelopment branch and a release development separately as illustratedin FIG. 6. The system maintains separate environment pipelines forprogram increment and release. The program increment branch is adevelopment branch where program increment development branch isutilized by the one or more users to develop one or more developmentcodes and move the development codes into iteration candidatesassociated with respective iteration cycles. Release development branchcomprises release candidates with multiple iteration candidatesassociated with multiple iteration cycles as illustrated in FIG. 6,wherein the release candidates from release development branch aredeployed into production environment.

As shown in block 308, the system initiates framework onboardingprocess, wherein the framework onboarding process comprises creatingframework candidates. Creation of framework candidates include gatheringapplication frameworks for a release cycle or an iteration cyclerequired for the development of application software. Applicationframework is a reusable program code that can be used by multipleapplications and is not specific to any one application. For example,application framework may be a library which can be a collection offunctions or objects, and/or the like. Each ruleset may comprise one ormore framework candidates. In some embodiments, the system automaticallycreates framework candidates. In alternate embodiments, the systemreceives framework candidates from any of the plurality of users. Insome embodiments, the framework candidates are created for everyiteration candidate. In some embodiments, the framework candidates arecreated for every iteration cycle. In such an embodiment, a user fromthe plurality of users may create a framework candidate associated withan iteration cycle and may submit it to the system via the smart tooluser interface. The system after receiving the framework candidate, mayassign a framework version number and store it in the first environmentsystem i.e., the development environment system 30. In some embodiments,the creation of framework candidates may be performed after or beforecreation of set of development codes by the plurality of users. In someembodiments, the framework candidates are created for every iterationcandidate. In some embodiments, the system creates the frameworkcandidates. In some embodiments, the system receives the frameworkcandidates along with the development codes from a user.

Additionally, the system may also receive one or more data instancesfrom the a user. Data instances are non-versioned data objects and maycontain data at a particular instance. For example, data instances arevalues assigned to a database table at an instance. In some embodiments,these data instances may be utilized by the set of development codesassociated with a rule-set to achieve one or more technical functions.

As shown in block 310, the system receives a set of development codesfrom one or more users, wherein each of the set of development codes isassociated with a rule-set. Each ruleset is associated with one or moretechnical features to be included in the application. As shown in block312, the system moves the set of development codes into an openiteration candidate, wherein the open iteration candidate is associatedwith a version number from the version range. In some embodiments, thesystem may move the set of development codes into the open iterationcandidate only after receiving an input from the one or more users tomove the set of development codes into the open iteration candidate. Inalternate embodiments, the system automatically moves the set ofdevelopment codes into the open iteration candidate as soon a user fromthe one or more users submits a development code from the set ofdevelopment codes. In some embodiments, the framework candidates anddata instances associated with each of the set of development codes aresubmitted by the user while submitting each of the set of developmentcodes. In such an embodiment, the system moves the framework candidatesand data instances associated with the each of the set of developmentcodes into the open iteration candidate while moving the set ofdevelopment codes.

As shown in block 314, the system stores each of the set of developmentcodes in the open iteration candidate in the first environment system.The first environment system is the development environment system 30.For example, the system receives first code associated with twotechnical features from a first user and may move the first code fromthe development branch to store the first code in a first iterationcandidate with a version number in the development environment system.

As shown in block 316, the system facilitates implementation of a firstunit test on each of the set of development codes stored in the firstenvironment system. This step may be performed before or after the stepsdescribed in block 312 and block 314. In other words, the system mayfacilitate implementation of a first unit test on each of the set ofdevelopment codes before moving and storing the set of the developmentcodes in open iteration candidate. The first unit test may be performedon each of the development codes received from the one or more users bya single user such as an application test engineer. Alternatively, thefirst unit test may be performed by the same user who submitted thedevelopment code (e.g., application developer). In some embodiments, thesystem monitors the first unit test on each of the development codes inthe first environment system to identify failure of the first unit teston any of the development codes. In some embodiments, when any of firstunit test cases associated with the first unit test fail, the systemautomatically notifies the user who submitted the development code tothe system about the failed first unit test cases. In such anembodiment, the user may make changes to the development code andresubmit the development code to the system. In alternate embodiments,the system performs first unit test after storing each of thedevelopment codes in the iteration candidate. In such an embodiment,when any of test cases associated with the first unit test fail, thesystem notifies the user associated with the development code. Once theuser resubmits the development code, the system may store theresubmitted development code in a new iteration candidate with a newversion number, wherein the new version number is consecutive to the oldversion number. In some embodiments, the development code resubmitted bythe user is stored in the same open iteration candidate. In someembodiments, after performing the first unit test on each of the set ofdevelopments codes stored in the iteration candidates, the system maysend the set of development codes to a set of users for review. In suchan embodiment, the set of users may review the set of development codesand submit an approval to the system.

As shown in block 318, the system verifies that each of the set ofdevelopment codes stored in the first environment system meets a set ofstandards. This step may be performed before performing the first unittest on each of the set of development codes or before moving andstoring the set of development codes in the iteration candidate. The setof standards may be rules or code development guidelines created by theresource entity system, wherein the set of standards ensure that the oneor more development codes have same coding conventions. In oneembodiment, wherein one development code submitted by a user does notmeet the set of standards, the system notifies the user and the userresubmits the development code. In some embodiments, the system verifiesthat each of the development codes meets the set of standards beforestoring each of the development codes in the iteration candidate.

As shown in block 320, the system creates a package comprising each ofthe set of development codes, framework candidates, and data instancesstored in the iteration candidate in the first environment system,thereby resulting in a packaged development code. The process ofpackaging of the development codes is discussed in detail in FIG. 6. Thesystem packages the set of development codes, framework candidates, anddata instances in multiple iteration candidates for multiple iterationcycles after receiving an input from a first user of the plurality ofusers. Upon packaging the set of development codes, frameworkcandidates, and data instances, the system locks the associatediteration candidates in which the set of development codes, theframework candidates, and the data instances are stored.

As shown in block 322, the system automatically deploys the packageddevelopment code from the first environment to at least one secondenvironment system. The second environment system may be the testingenvironment system 40 or the acceptance test environment system. Thesystem stores the packaged development code with the associatediteration candidate version number. The process described in block 310through block 322 may be repeated for multiple iteration candidates inone iteration cycle. Similarly, the process may be repeated for multipleiteration cycles.

As shown in block 324, the system restarts the application softwareassociated with the packaged development code. To reflect the changesassociated with the packaged development code, the system restarts thealready running application software in the at least one secondenvironment system. However, in some embodiments, restart of theapplication software is not required to reflect the changes. In such anembodiment, the system intelligently identifies that the restart of theapplication software is not required based on the type of the packageddevelopment code. As shown in block 326, the system performs a rulediagnostic test to verify that the packaged development code deployed tothe at least one second environment system meets version requirements ofthe at least one second environment system. For example, the at leastone second environment system may comprise version ‘01-01-08’ of aniteration candidate and the development environment system may compriseversion ‘01-01-10’ of the an iteration candidate. The system performsthe rule diagnostic test to identify that the packaged development codehas only version ‘01-01-09’ and version ‘01-01-10’ and may repeat theprocess of packaging and deployment upon determining the failure of therule diagnostic test.

As shown in block 328, the system performs an integration diagnosticcheck to verify that one or more connections with a plurality of systemsare active. The system may be communicating with one or more systems orapplications to performs various functions and the system performs theintegration diagnostic test to verify whether the connections areactive. For example, the application software may be linked with adatabase and the system may be connected to the database system. Thesystem performs the integration diagnostic check to verify that thedatabase connection is active. In the case that the database connectionor any other connections with the plurality of systems are not active,the application software may not perform as it is expected to. Afterdetermining that the one or more connections with the plurality ofsystems are not active, the system reestablishes the inactiveconnections and performs a second integration diagnostic check to verifythat all the one or more connections are active. The system repeats thisstep until it determines that all one or more connections are active.

As shown in block 330, the system facilitates implementation of aplurality of tests on the packaged development code deployed to the atleast one second environment system. The system facilitatesimplementation of the regression test, the second unit test, the useracceptance test, and the performance test before deploying the packageddevelopment code to the third environment system. In some embodiments,the system may automatically run scripts associated with the pluralityof tests. In alternate embodiments, the system may transfer the packageddevelopment codes to a plurality of users to perform the plurality oftests. In such an embodiment, the plurality of users perform theplurality of tests and notify the system if each of the plurality oftests are successful or unsuccessful. As shown in block 332, the systemverifies that the packaged development code has passed the plurality oftests. The process illustrated from block 310 to block 332 is performedfor ‘n’ number of iteration cycles before deploying the packageddevelopment codes to a third environment system, wherein a packageddevelopment code exists for each of the iteration candidates in ‘n’iteration cycles associated with a release cycle. The system mayre-package the one or more packaged development codes associated withthe release cycle and move the repackaged development codes into openrelease candidates under the release development branch. At the end ofthe release cycle, the repackaged development codes existing in arelease candidate associated with the release cycle are deployed to thethird environment system. The system may assign a release candidateversion number from the version ranges calculated in block 306 to therelease candidates associated with the release cycle. In someembodiments, only one iteration cycle may exist for a release cycle.

As shown in block 334, the system in response to verifying, deploys thepackaged development code to the third environment system. The thirdenvironment system is the production environment system, wherein theapplication software is delivered to the plurality of end users of theapplication software. In some embodiments, wherein any of the pluralityof tests fail, the system notifies the users associated with thedevelopment of the set of development codes in the packaged developmentcode. The users may resubmit the set of development codes. The systemopens a new release candidate to store the set of development codesresubmitted by the users, wherein the new release candidate is assigneda new release candidate version number which is consecutive to a versionnumber of an existing release candidate. In some embodiments, the systemidentifies a development code of the set of development codes in thepackaged development code which resulted in any of the plurality oftests to fail and notifies the user associated with that developmentcode.

As shown in block 336, the system validates the packaged developmentcode in response to deploying the packaged development code to the thirdenvironment system. Validation of the packaged development code is toverify that the technical features of the packaged development code whenintegrated into the production environment system function properlywithout disrupting other functions or features of the applicationsoftware. In other words, the system verifies that new changes in thepackaged development code when deployed to the production environmentsystem, did not make the application software unstable. As shown inblock 338, the system determines if the validation of the packageddevelopment code is successful. As shown in block 340, the system upondetermining that the validation of the packaged development code issuccessful, restarts the application software associated with thepackaged development code. Restarting the application software in theproduction environment system pushes the new changes in the packageddevelopment codes to the plurality of end users of the applicationsoftware. The plurality of end users may access the application softwarevia an end user computing system, an end user mobile system, and/or thelike. In some embodiments, the system upon determining that thevalidation of the packaged development code is successful, restarts theapplication software associated with the packaged development code onlyafter determining that the restarting the application software isrequired. For example, some new changes may be reflected directlywithout restarting the application software.

As shown in block 342, the system upon determining that the validationof the packaged development code is unsuccessful, rolls back thepackaged development code deployed to the third environment system. Forexample, when the system identifies that the new changes in the packageddevelopment code associated with the deployment version have made theapplication software unstable, the system rolls back to the most stabledeployment version. If the most stable deployment version was ‘08-11-06’and the recent packaged deployment version is ‘08-11-07’ the systemrolls back to version ‘08-11-06’ after determining that the deploymentversion ‘08-11-07’ has made the application software unstable. In someembodiments, the system automatically notifies the one or more usersassociated with each of the set of development codes in the packageddevelopment code and may repeat the process flow 300.

FIG. 4 illustrates a general process flow for ruleset versioning andmoving the development codes received from the user into iterationcandidates and release candidates based on the duration of the iterationcycles and the release cycles. As shown in block 410, the systemreceives a first development code associated with a first rule-set froma first user, wherein the first user transfers the first developmentcode via a smart tool user interface. In some embodiments, the firstuser accesses the smart tool user interface and develops the firstdevelopment code temporarily under the program increment developmentbranch previously created during the application onboarding process. Thesmart tool user interface is provided by the smart CICD application onthe user computer system 20.

Next, as shown in block 420, the system in response to receiving thefirst development code from the first user, moves the first developmentcode into an open first iteration candidate with a first version number,wherein the first iteration candidate is opened during the applicationonboarding process as discussed in block 306. The first development codemay be associated with a first technical feature of a plurality oftechnical features associated with a first iteration cycle and a firstrelease cycle of the application software. In some embodiments, thefirst development code may be associated with more than one technicalfeature of the plurality of technical features. In some embodiments, thesystem moves the first development code after receiving a ‘move’ inputfrom the first user. In alternate embodiments, the system automaticallymoves the first development code to the first iteration candidate withthe first version number.

As shown in block 430, the system receives an input from the first userto lock the first iteration candidate. At this point, the firsttechnical feature may or may not be complete. Locking of the firstiteration candidates prevents any other users from moving developmentcodes to the first iteration candidates. In some embodiments, the firstuser may lock the first iteration candidate after submitting more thanone development code associated with more than one technical feature. Insome embodiments, the first user may lock the first iteration candidateafter submitting a single development code associated with a singletechnical feature. As shown in block 440, the system in response toreceiving the input from the first user, locks the first iterationcandidate.

As shown in block 450, the system in response to locking the firstiteration candidate, closes the first iteration candidate and opens asecond iteration candidate with a second version number, wherein thefirst version number associated with the first iteration candidate andthe second version number associated with the second iteration candidateare consecutive numbers. The system assigns version numbers to the newlyopened iteration candidates by identifying the old version number of theprevious iteration candidate already existing in the first environmentsystem and assigning a new version number consecutive to the old versionnumber. For example, the system after identifying that the old versionnumber of the existing iteration candidate is ‘01-01-01,’ assignsversion number ‘01-01-02’ to the newly opened iteration candidate. Theversion numbers assigned to the iteration candidates are from theversion ranges created by the system during the application onboardingprocess as discussed in block 306.

Next, as shown in block 460, the system receives a second developmentcode from a second user of the one or more users. In some embodiments,the second development code is associated with a second feature of theplurality of technical features. In some other embodiments, wherein thefirst technical feature is incomplete at the time the first iterationcandidate was locked, the second development code is associated with thefirst technical feature. In some embodiments, the system receives thesecond development code from the first user who submitted the firstdevelopment code. The first user and the second user may be employees ofthe resource entity. For example, the first user and the second user maybe application developers. As shown in block 470, the system moves thesecond development code received from the second user to the seconditeration candidate. The system may follow similar process for assigningversion numbers to release candidates which is illustrated in FIG. 6.However, the release candidates comprise one or more iterationcandidates associated with an iteration cycle. The system may moveiteration candidates into an open release candidate at the end of eachiteration cycle. In some embodiments, the system may move the iterationcandidates only after receiving an input from a user. The system aftermoving the iteration candidates into the open release candidate, closesthe open release candidate and opens a new release candidate with a newversion number, wherein the new version number is consecutive to thepreviously open release candidate version number.

FIG. 5 presents a block diagram 500 illustrating the process ofdeployment of an application software in multiple release cycles anditeration cycles. Iteration development 502, as shown in FIG. 5,comprises development of one or more development codes, data instances,framework candidates by plurality of users. Upon development, theplurality of users submit the one or more development codes, datainstances, and framework candidates to the system and the system storesthe one or more development codes, data instances, and frameworkcandidates in the first environment system i.e., the developmentenvironment system. The one or more development codes may be associatedwith multiple rule-sets. As shown in section 504, the system packagesthe one or more development codes, data instances, and frameworkcandidates associated with a particular iteration cycle. As shown insection 506, each iteration cycle comprises one or more iterationcandidates. For example, iteration 1 comprises candidate 1, candidate 2,candidate 3, candidate 4, and candidate 5 as shown in FIG. 5. Each ofthe iteration candidates comprise one or more development codes, datainstances, and framework candidates associated with one or morerule-sets and may be associated with one or more technical features. Alliteration candidates associated with each iteration cycle are thentransferred to testing environment system and the acceptance testenvironment system as shown in section 510. Once all iterationcandidates have passed the plurality of tests, the system may createrelease candidates by packaging all iteration candidates associated withmultiple iteration cycles as shown in section 512 and section 514.Release of the application software may be performed in multiple stagesi.e., each of the release candidates may be deployed to the productionenvironment system immediately after packaging. In some otherembodiments, one or more release candidates may be combined together anddeployed at the end of a release cycle to the production environmentsystem as shown in section 516 and section 518.

FIG. 6 illustrates ruleset versioning and creation of iterationcandidates and release candidates. As explained in block 306, the systemcreates program increment development branch 601 in the firstenvironment system (i.e., development environment system) for allowingthe plurality of users to temporarily develop one or more developmentcodes before storing the one or more development codes received from theplurality of users in iteration candidates. The system also assignsversion range ‘01-01-99’ to the program increment development branch601, wherein the iteration candidates under the development branch 601have version numbers from ‘01-01-01’ through ‘01-01-99’. The systemafter creating the program increment development branch 601, opens aniteration candidate 1 ‘01-01-01’ 621 with a version number from thepreviously set version range ‘01-01-99’. The system may receive a firstdevelopment code or a change set 1 associated with a first feature froma first user (Developer 1) as shown in block 602 and may move the firstdevelopment code into the open iteration candidate with version number‘01-01-01’ 621 as shown in FIG. 6. The first user may submit the firstdevelopment code via the smart tool user interface. In some embodiments,the system may also receive framework candidates and data instancesassociated with the first development code from the first user. In someembodiments, the system may receive framework candidates and datainstances for the first feature before receiving the first developmentcode.

The system may receive a second development code or change set 2 from afirst user or a second user (Developer 2) of the plurality of users asshown in block 603. In some embodiments, the second development code isan incremental change to the first development code. In someembodiments, the second development code is associated with the firstfeature. In some embodiments, the second development code is associatedwith a second feature. In the current example, as shown in FIG. 6, thesystem after receiving the second development code from the first useror the second user, moves the second development code into the openiteration candidate 1 ‘01-01-02’ 621.

The system may then receive an input from the first user or the seconduser to lock the iteration candidate 1 ‘01-01-01’ 621 comprising thefirst development code of block 602 and the second development code ofblock 603 as explained in process flow 400 of FIG. 4. In someembodiments, the first feature may be complete at the time the systemreceives the input. In alternate embodiments, the first feature may beincomplete at the time the system receives the input. The system, inresponse to receiving the input from the first user or the second user,locks the iteration candidate 1 ‘01-01-01’ 621 comprising the firstdevelopment code and the second development code. At this point thesystem locks the iteration candidate 1 ‘01-01-01’ 621 and closes it. Thesystem in response to closing the iteration candidate ‘1’ 621, opens theiteration candidate 2 ‘01-01-02’ 622 for receiving one or moredevelopment codes associated with the first feature and/or otherfeatures. In some embodiments, the system may package the iterationcandidate 1 ‘01-01-01’ and then deploy the iteration candidate 1‘01-01-01’ 621 into the second environment system i.e., testingenvironment system. In some embodiments, the system automaticallydeploys the iteration candidate 1 ‘01-01-01’ 621 based on rules createdas part of the application onboarding process. In some embodiments, thesystem deploys the iteration candidate 1 ‘01-01-01’ 621 to the secondenvironment system only after receiving a deploy input from any of theplurality of users. A plurality of tests are performed on the iterationcandidate ‘1’ 621 as explained in block 330. In other embodiments, thesystem may package the iteration candidate 1 ‘01-01-01’ 621 and otheriteration candidates associated with an iteration cycle and deploy theiteration candidate 1 ‘01-01-01’ 621 into the second environment systemalong with other iteration candidates.

The system then receives a third development code or change set 3associated with the first feature from the first user, a second user, ora third user (Developer 3) of the plurality of users as shown in block604, and moves and stores the third development code in the iterationcandidate 2 ‘01-01-02’ 622′. The system may then receive a second inputfrom any of the plurality of users to close the iteration candidate 2‘01-01-02’ 622. Upon receiving the input, the system closes theiteration candidate 2 ‘01-01-02’ 622 and opens iteration candidate 3‘01-01-03’ 623. Similarly, the system may receive fourth developmentcode or change set 4 from a fourth user (developer 4) as shown in block605 and may move the fourth development code to the iteration candidate3 ‘01-01-03’ 623. The system upon receiving an input from the user, mayclose the iteration candidate 3 ‘01-01-03’ 623 and open an iterationcandidate 4 ‘01-01-04’ 624 to store a fifth development code receivedfrom a fifth user (developer 5) as shown in block 606. In someembodiments, the system may package and deploy both the iterationcandidate ‘1’ 621 and the iteration candidate ‘2’ 622 into the secondenvironment system together, but in the current example shown in theFIG. 6 the system packages and deploys iteration candidate 1 ‘01-01-01’621 through iteration candidate 4 ‘01-01-04’ 624 associated withiteration 1 630. After successful testing the second environment system,the system moves iteration candidates associated with iteration cycle 1630 (change set from iteration 1 as shown in block 611) into a releasecandidate 1 ‘02-01-01’ 640 open at the time in a release developmentbranch 610 with version range ‘02-01-99’ created by the system duringthe application onboarding process as explained in block 306 previously.

Similarly, the system receives multiple development codes (change set 6of block 607, change set 7 of block 608, . . . change set N of block609) from the plurality of users(Developer 6 of block 607, Developer 7of block 608, . . . Developer N of block 609 respectively), moves andstores the multiple development codes in open iteration candidates(iteration candidate 5 ‘01-01-05’ 625 through iteration candidate N‘01-01-98’ 626) associated with multiple iteration cycles (iterationcycle ‘2’ 631 through iteration ‘N’ 632). The system then packages anddeploys the iteration candidates associated with multiple iterationcycles into second environment system as explained above. Aftersuccessful testing, the system moves the iteration candidates (e.g.,change set from iteration ‘2’ 612 through change set from iteration ‘N’614)associated with multiple iteration cycles (e.g., iteration ‘2’ 631through iteration ‘N’ 632) into release candidates (e.g., releasecandidate 2 ‘02-01-02’ of block 642 . . . release candidate N ‘02-01-98’of block 627) open at the time. In the case, where any of the tests ondevelopment codes stored in the iteration candidates fail during testingin the second environment system, a user of the plurality of users maysubmit a new development code (Developer X submitting Change Y as shownin block 613). Upon receiving the new development code, the system movesthe new development code into an open release candidate 3 ‘02-01-03’644. In some embodiments, the system may close an existing releasecandidate and open a new release candidate to store the new developmentcode. The release candidates associated with multiple release cycles(e.g., Release ‘1’ 650) may be packaged and deployed into thirdenvironment system (i.e., production environment system) at the end ofeach of the multiple release cycles. In the current example, as shown inFIG. 6, it is shown that all release candidates are combined, packaged,and deployed into the third environment system at the end of releasecycle 1 650. However, in some embodiments, only release candidate 1‘02-01-01’ through release candidate 3 ‘02-01-03’ may be released intothe third environment system under release cycle 1 650.

Software integration and deployment of a software application may beperformed in multiple release cycles (e.g., release cycle ‘1’ 650,release cycle ‘2’ 652 . . . release cycle ‘N’ 656). In some embodiments,development of an application software may be performed in onedevelopment branch. In some other embodiments, development of anapplication software may be performed in one or more developmentbranches. There may be multiple software applications which are beingdeployed and integrated continuously on a daily basis within an entity.Smart CICD tool allows for continuous integration and deployment ofmultiple software applications simultaneously.

The integration and deployment of software applications will depend onmultiple development lifecycles models. Development lifecycles modelsmay include, but not limited to, agile model, waterfall model, spiralmethod, and/or the like. A plurality of teams within a single resourceentity may choose different development life cycles models. The smartCICD tool automatically adapts itself to the type of developmentlifecycle model selected by each team and supports the process ofintegration and deployment based on the selected development lifecyclemodel.

FIG. 7 illustrates of orchestration of the software integration anddeployment process in one or more environment systems by the smart tool.FIG. 7 illustrates an example of the software integration and deploymentprocess wherein there is only one iteration cycle in a release candidateand wherein there is only one release candidate in a release cycle. Inthis figure, the iteration candidates and release candidates arediscussed without their version numbers for exemplary purposes only. Theiteration candidates and release candidates have version numbers asexplained in previous figures. As shown in the figure, between time t0and time t1 an iteration candidate ‘1’ 710 is developed in thedevelopment environment 702. At the beginning of time t1, the iterationcandidate ‘1’ 710 may be deployed to the testing environment 704 andbetween time t1 and time t2 iteration candidate ‘2’ 720 and iterationcandidate ‘3’ 730 may be developed in the development environmentconsecutively. At the beginning of time t2, iteration candidate ‘2’ 720and iteration candidate ‘3’ 730 are deployed to testing environment 704and in between time t2 and time t3, iteration candidate ‘2.1’ isdeveloped in the development environment 702.

At the beginning of time t3, the iteration candidate ‘1’ 710, iterationcandidate ‘2’ 720 and iteration candidate ‘3’ 730 which are part of oneiteration cycle are packaged into a release candidate ‘1’ 770 and aredeployed into user acceptance testing environment 706 and iterationcandidate ‘2.1’ 740 is deployed into testing environment 704. Iterationcandidate ‘3.1’ 750 is developed between time t3 and time t4.

At the beginning of time t4, the release candidate ‘1’ 770, aftersuccessful testing is deployed to the production environment 708 as partof a release cycle. In this example, there is only one release candidatein the first release cycle. At the beginning of time t4, the iterationcandidate ‘2.1’ 740 is packaged into a release candidate 2.1 780 anddeployed into the user acceptance testing environment 706 and iterationcandidate ‘3.1’ 750 is deployed to testing environment 704. Iterationcandidate ‘3.2’ 760 is developed between time t4 and time t5. As such,the smart CICD orchestrates the deployment of development codes intomultiple environment systems simultaneously.

Although many embodiments of the present invention have just beendescribed above, the present invention may be embodied in many differentforms and should not be construed as limited to the embodiments setforth herein; rather, these embodiments are provided so that thisdisclosure will satisfy applicable legal requirements. Also, it will beunderstood that, where possible, any of the advantages, features,functions, devices, and/or operational aspects of any of the embodimentsof the present invention described and/or contemplated herein may beincluded in any of the other embodiments of the present inventiondescribed and/or contemplated herein, and/or vice versa. In addition,where possible, any terms expressed in the singular form herein aremeant to also include the plural form and/or vice versa, unlessexplicitly stated otherwise. Accordingly, the terms “a” and/or “an”shall mean “one or more,” even though the phrase “one or more” is alsoused herein. Like numbers refer to like elements throughout.

As will be appreciated by one of ordinary skill in the art in view ofthis disclosure, the present invention may include and/or be embodied asan apparatus (including, for example, a system, machine, device,computer program product, and/or the like), as a method (including, forexample, a business method, computer-implemented process, and/or thelike), or as any combination of the foregoing. Accordingly, embodimentsof the present invention may take the form of an entirely businessmethod embodiment, an entirely software embodiment (including firmware,resident software, micro-code, stored procedures in a database, or thelike), an entirely hardware embodiment, or an embodiment combiningbusiness method, software, and hardware aspects that may generally bereferred to herein as a “system.” Furthermore, embodiments of thepresent invention may take the form of a computer program product thatincludes a computer-readable storage medium having one or morecomputer-executable program code portions stored therein. As usedherein, a processor, which may include one or more processors, may be“configured to” perform a certain function in a variety of ways,including, for example, by having one or more general-purpose circuitsperform the function by executing one or more computer-executableprogram code portions embodied in a computer-readable medium, and/or byhaving one or more application-specific circuits perform the function.

It will be understood that any suitable computer-readable medium may beutilized. The computer-readable medium may include, but is not limitedto, a non-transitory computer-readable medium, such as a tangibleelectronic, magnetic, optical, electromagnetic, infrared, and/orsemiconductor system, device, and/or other apparatus. For example, insome embodiments, the non-transitory computer-readable medium includes atangible medium such as a portable computer diskette, a hard disk, arandom access memory (RAM), a read-only memory (ROM), an erasableprogrammable read-only memory (EPROM or Flash memory), a compact discread-only memory (CD-ROM), and/or some other tangible optical and/ormagnetic storage device. In other embodiments of the present invention,however, the computer-readable medium may be transitory, such as, forexample, a propagation signal including computer-executable program codeportions embodied therein. In some embodiments, memory may includevolatile memory, such as volatile random access memory (RAM) having acache area for the temporary storage of information. Memory may alsoinclude non-volatile memory, which may be embedded and/or may beremovable. The non-volatile memory may additionally or alternativelyinclude an EEPROM, flash memory, and/or the like. The memory may storeany one or more of pieces of information and data used by the system inwhich it resides to implement the functions of that system.

One or more computer-executable program code portions for carrying outoperations of the present invention may include object-oriented,scripted, and/or unscripted programming languages, such as, for example,Java, Perl, Smalltalk, C++, SAS, SQL, Python, Objective C, JavaScript,and/or the like. In some embodiments, the one or morecomputer-executable program code portions for carrying out operations ofembodiments of the present invention are written in conventionalprocedural programming languages, such as the “C” programming languagesand/or similar programming languages. The computer program code mayalternatively or additionally be written in one or more multi-paradigmprogramming languages, such as, for example, F#.

Some embodiments of the present invention are described herein withreference to flowchart illustrations and/or block diagrams of apparatusand/or methods. It will be understood that each block included in theflowchart illustrations and/or block diagrams, and/or combinations ofblocks included in the flowchart illustrations and/or block diagrams,may be implemented by one or more computer-executable program codeportions. These one or more computer-executable program code portionsmay be provided to a processor of a general purpose computer, specialpurpose computer, and/or some other programmable data processingapparatus in order to produce a particular machine, such that the one ormore computer-executable program code portions, which execute via theprocessor of the computer and/or other programmable data processingapparatus, create mechanisms for implementing the steps and/or functionsrepresented by the flowchart(s) and/or block diagram block(s).

The one or more computer-executable program code portions may be storedin a transitory and/or non-transitory computer-readable medium (e.g., amemory or the like) that can direct, instruct, and/or cause a computerand/or other programmable data processing apparatus to function in aparticular manner, such that the computer-executable program codeportions stored in the computer-readable medium produce an article ofmanufacture including instruction mechanisms which implement the stepsand/or functions specified in the flowchart(s) and/or block diagramblock(s).

The one or more computer-executable program code portions may also beloaded onto a computer and/or other programmable data processingapparatus to cause a series of operational steps to be performed on thecomputer and/or other programmable apparatus. In some embodiments, thisproduces a computer-implemented process such that the one or morecomputer-executable program code portions which execute on the computerand/or other programmable apparatus provide operational steps toimplement the steps specified in the flowchart(s) and/or the functionsspecified in the block diagram block(s). Alternatively,computer-implemented steps may be combined with, and/or replaced with,operator- and/or human-implemented steps in order to carry out anembodiment of the present invention.

While certain exemplary embodiments have been described and shown in theaccompanying drawings, it is to be understood that such embodiments aremerely illustrative of and not restrictive on the broad invention, andthat this invention not be limited to the specific constructions andarrangements shown and described, since various other changes,combinations, omissions, modifications and substitutions, in addition tothose set forth in the above paragraphs, are possible. Those skilled inthe art will appreciate that various adaptations, modifications, andcombinations of the just described embodiments can be configured withoutdeparting from the scope and spirit of the invention. Therefore, it isto be understood that, within the scope of the appended claims, theinvention may be practiced other than as specifically described herein.

What is claimed is:
 1. A system for enterprise-wide version control ofcodes during software integration and deployment, the system comprising:at lease one non-transitory computer readable medium including one ormore memory devices; one or more processing devices; a smart tool storedin the one or more memory devices, the smart tool comprising one or moremodules with instructions executable by the one or more processingdevices operatively coupled to the one or more memory devices, whereinthe one or more processing devices are configured for executing theinstructions to: create a program increment development branch in afirst environment system, wherein the program increment developmentbranch comprises a program increment version range; open a firstiteration candidate under the program increment development branch witha first iteration version number, wherein the first iteration versionnumber is associated with the program increment version range; create arelease development branch in the first environment system, wherein therelease development branch comprises a release version range; open afirst release candidate under the release development branch with afirst release version number, wherein the first release version numberis associated with the release version range; receive at least one firstdevelopment code associated with a first ruleset from a first user via asmart tool user interface; receive a first data instance and a firstframework candidate associated with the first development code from thefirst user via the smart tool user interface; in response to receivingthe first development code, verify that the first development code doesmeet a set of standards; notify the first user that the firstdevelopment code does not meet the set of standards and prompt the firstuser to submit a first new development code; receive the first newdevelopment code associated with the first ruleset from the first user;verify that the first new development code meets the set of standards;move the first new development code, the first data instance, and thefirst framework candidate to the first iteration candidate; receive afirst input from the first user to lock the first iteration candidate;lock the first iteration candidate based on receiving the first inputfrom the first user and close the first iteration candidate; and createa package of the first iteration candidate comprising the first datainstance, the first framework candidate and the first new developmentcode.
 2. The system of claim 1, wherein the one or more processingdevices are configured for executing the instructions in the one or moremodules to deploy the first iteration candidate to a second environmentsystem in response to creating the package of the first iterationcandidate, wherein the second environment system is a testingenvironment system or an acceptance test environment system.
 3. Thesystem of claim 1, wherein the one or more processing devices areconfigured for executing the instructions in the one or more modules to:in response to closing the first iteration candidate, open a seconditeration candidate under the program increment development branch witha second iteration version number, wherein the second iteration versionnumber is consecutive to the first iteration version number; receive asecond development code associated with the first ruleset from at leastone of the first user or a second user; in response to receiving thesecond development code, move the second development code to the seconditeration candidate; receive a second input from at least one of thefirst user or the second user to lock the second iteration candidate;lock the second iteration candidate based on receiving the second inputfrom at least one of the first user or the second user and close thesecond iteration candidate; and in response to closing the seconditeration candidate, open a third iteration candidate under the programincrement development branch with a third iteration version number,wherein the third iteration version number is consecutive to the seconditeration version number.
 4. The system of claim 3, wherein the one ormore processing devices are configured for executing the instructions inthe one or more modules to deploy the first iteration candidate and thesecond iteration candidate to a second environment system in response toclosing the second iteration candidate.
 5. The system of claim 4,wherein the one or more processing devices are configured for executingthe instructions in the one or more modules to: in response to deployingthe first iteration candidate and the second iteration candidate to thesecond environment system, perform a plurality of tests on the firstiteration candidate and the second iteration candidate; determine thatthe plurality of tests on the first iteration candidate and the seconditeration candidate are successful; move the first iteration candidateand the second iteration candidate to the first release candidate withthe first release version number.
 6. The system of claim 5, wherein theone or more processing devices are configured for executing theinstructions in the one or more modules to: deploy the first releasecandidate to a third environment system on a predetermined cycle enddate associated with a first release cycle, wherein the thirdenvironment system is a production environment system.
 7. The system ofclaim 6, wherein the one or more processing devices are configured forexecuting the instructions in the one or more modules to open a secondrelease candidate under the release development branch with a secondrelease version number in response to deploying the first releasecandidate to the third environment system, wherein the second releaseversion number is associated with the release version range and isconsecutive to the first release version number.
 8. The system of claim1, wherein the first new development code and the second developmentcode are incremental changes.
 9. The system of claim 1, wherein thefirst new development code and second development are associated with asingle feature.
 10. The system of claim 1, wherein the first newdevelopment code and the second development code are associated withdifferent features.
 11. A computer program product for enterprise-wideversion control of codes during software integration and deployment, thecomputer program product comprising at least one non-transitory computerreadable medium comprises computer readable instructions for: creating aprogram increment development branch in a first environment system,wherein the program increment development branch comprises a programincrement version range; opening a first iteration candidate under theprogram increment development branch with a first iteration versionnumber, wherein the first iteration version number is associated withthe program increment version range; creating a release developmentbranch in the first environment system, wherein the release developmentbranch comprises a release version range; opening a first releasecandidate under the release development branch with a first releaseversion number, wherein the first release version number is associatedwith the release version range; receiving at least one first developmentcode associated with a first ruleset from a first user via a smart tooluser interface; receiving a first data instance and a first frameworkcandidate associated with the first development code from the first uservia the smart tool user interface; in response to receiving the firstdevelopment code, verifying that the first development code does meet aset of standards; notifying the first user that the first developmentcode does not meet the set of standards and prompt the first user tosubmit a first new development code; receiving the first new developmentcode associated with the first ruleset from the first user; verifyingthat the first new development code meets the set of standards; movingthe first new development code, the first data instance, and the firstframework candidate to the first iteration candidate; receiving a firstinput from the first user to lock the first iteration candidate; lockingthe first iteration candidate based on receiving the first input fromthe first user and closing the first iteration candidate; and creating apackage of the first iteration candidate comprising the first datainstance, the first framework candidate and the first new developmentcode.
 12. The computer program product of claim 11, wherein thenon-transitory computer readable medium comprises computer readableinstructions for deploying the first iteration candidate to a secondenvironment system in response to creating the package of the firstiteration candidate, wherein the second environment system is a testingenvironment system or an acceptance test environment system.
 13. Thecomputer program product of claim 11, wherein the non-transitorycomputer readable medium comprises computer readable instructions for:in response to closing the first iteration candidate, opening a seconditeration candidate under the program increment development branch witha second iteration version number, wherein the second iteration versionnumber is consecutive to the first iteration version number; receiving asecond development code associated with the first ruleset from at leastone of the first user or a second user; in response to receiving thesecond development code, moving the second development code to thesecond iteration candidate; receiving a second input from at least oneof the first user or the second user to lock the second iterationcandidate; locking the second iteration candidate based on receiving thesecond input from at least one of the first user or the second user andclosing the second iteration candidate; and in response to closing thesecond iteration candidate, opening a third iteration candidate underthe program increment development branch with a third iteration versionnumber, wherein the third iteration version number is consecutive to thesecond iteration version number.
 14. The computer program product ofclaim 13, wherein the non-transitory computer readable medium comprisescomputer readable instructions for deploying the first iterationcandidate and the second iteration candidate to a second environmentsystem in response to closing the second iteration candidate.
 15. Thecomputer program product of claim 14, wherein the non-transitorycomputer readable medium comprises computer readable instructions for:in response to deploying the first iteration candidate and the seconditeration candidate to the second environment system, performing aplurality of tests on the first iteration candidate and the seconditeration candidate; determining that the plurality of tests on thefirst iteration candidate and the second iteration candidate aresuccessful; moving the first iteration candidate and the seconditeration candidate to the first release candidate with the firstrelease version number.
 16. The computer program product of claim 15,wherein the non-transitory computer readable medium comprises computerreadable instructions for deploying the first release candidate to athird environment system on a predetermined cycle end date associatedwith a first release cycle, wherein the third environment system is aproduction environment system.
 17. A computer implemented method forenterprise-wide version control of codes during software integration anddeployment, the computer implemented method comprising: creating aprogram increment development branch in a first environment system,wherein the program increment development branch comprises a programincrement version range; opening a first iteration candidate under theprogram increment development branch with a first iteration versionnumber, wherein the first iteration version number is associated withthe program increment version range; creating a release developmentbranch in the first environment system, wherein the release developmentbranch comprises a release version range; opening a first releasecandidate under the release development branch with a first releaseversion number, wherein the first release version number is associatedwith the release version range; receiving at least one first developmentcode associated with a first ruleset from a first user via a smart tooluser interface; receiving a first data instance and a first frameworkcandidate associated with the first development code from the first uservia the smart tool user interface; in response to receiving the firstdevelopment code, verify that the first development code does meet a setof standards; notify the first user that the first development code doesnot meet the set of standards and prompt the first user to submit afirst new development code; receive the first new development codeassociated with the first ruleset from the first user; verify that thefirst new development code meets the set of standards; moving the firstnew development code, the first data instance, and the first frameworkcandidate to the first iteration candidate; receiving a first input fromthe first user to lock the first iteration candidate; locking the firstiteration candidate based on receiving the first input from the firstuser and close the first iteration candidate; and creating a package ofthe first iteration candidate comprising the first data instance, thefirst framework candidate and the first new development code.
 18. Thecomputer implemented method of claim 17, wherein the computerimplemented method further comprises deploying the first iterationcandidate to a second environment system in response to creating thepackage of the first iteration candidate, wherein the second environmentsystem is a testing environment system or an acceptance test environmentsystem.
 19. The computer implemented method of claim 17, wherein thecomputer implemented method further comprises: in response to closingthe first iteration candidate, opening a second iteration candidateunder the program increment development branch with a second iterationversion number, wherein the second iteration version number isconsecutive to the first iteration version number; receiving a seconddevelopment code associated with the first ruleset from at least one ofthe first user or a second user; in response to receiving the seconddevelopment code, moving the second development code to the seconditeration candidate; receiving a second input from at least one of thefirst user or the second user to lock the second iteration candidate;locking the second iteration candidate based on receiving the secondinput from at least one of the first user or the second user and closingthe second iteration candidate; and in response to closing the seconditeration candidate, opening a third iteration candidate under theprogram increment development branch with a third iteration versionnumber, wherein the third iteration version number is consecutive to thesecond iteration version number.
 20. The computer implemented method ofclaim 19, wherein the computer implemented method further comprises:deploying the first iteration candidate and the second iterationcandidate to a second environment system in response to closing thesecond iteration candidate; in response to deploying the first iterationcandidate and the second iteration candidate to the second environmentsystem, performing a plurality of tests on the first iteration candidateand the second iteration candidate; determining that the plurality oftests on the first iteration candidate and the second iterationcandidate are successful; moving the first iteration candidate and thesecond iteration candidate to the first release candidate with the firstrelease version number.